Abstract
In modern joining technology, the focus is on effective brazing and soldering of temperature sensitive materials. Here, as well as in diffusion welding processes the needed thermal energy is externally realized in the joint zone. This produces a heating of the whole joining parts, since in laminar joining the thermal energy is transported in interior by thermal conduction. An excess of critical temperatures or tolerable impact periods in wide parts of materials and respectively components is often not avoidable. This leads to thermal damages. In this point of view nanotechnology shows promising possibilities as scale effects and their resulting thermophysical effects such as melting temperature reduction and high diffusion rates can be used for providing a self-propagating high-temperature synthesis at room temperature. After ignition by an external energy source a self-propagating exothermic reaction is started. By producing a multilayer system with alternately arranged nanoscaled layers of e.g. Al and Ni the resulting thin foil can be used as heat source for melting the braze or solder material within the joining zone without any external preheating. Due to the high process velocities up to 30 m/s and the local heat input significant thermal influences on the joined parts are not detectable.
Highlights
The fulfillment of the high requirements on modern technical components focuses on new joining technologies
In this point of view nanotechnology shows promising possibilities as scale effects and their resulting thermophysical effects such as melting temperature reduction and high diffusion rates can be used for providing a self-propagating high-temperature synthesis at room temperature
By producing a multilayer system with alternately arranged nanoscaled layers of e.g. Al and Ni the resulting thin foil can be used as heat source for melting the braze or solder material within the joining zone without any external preheating
Summary
The fulfillment of the high requirements on modern technical components focuses on new joining technologies. Due to the temperature sensitivity of new high-strengthened materials and the challenges given by new aspects in economizing, such as light-weight constructions, conventional joining processes show several disadvantages which have to be overcome successfully In this point of view nanotechnology plays an important role to meet the requirements as completely new properties are given by size effects and nanoadhesion. One possibility is the use of SHS-Effect which is well known since the mid 60’s of the 20th century It is based on the use of negative enthalpy between different elements to start a self-propagating reaction. By applying these selfpropagating reactions in thin foils it is possible to provide the necessary energy for melting braze/solder material within the joining area without external heating. The joining technology shows high potential for a wide application range, starting from classical mechanical engineering towards applications in electronics industry
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